DE2630618A1 - CONTROL CIRCUIT FOR A GAS DISCHARGE DISPLAY PANEL - Google Patents

Description

The invention relates to a circuit for driving a gas discharge display panel, in particular a gas discharge display panel with outer electrode ^ which is generally referred to as a plasma display panel.

A gas discharge display panel has opposing electrode groups, each on both Sides of a gas discharge space are arranged, either as a continuous, filled with ionizable gas Space or can be designed as a plurality of equal spaces, which are referred to as gas discharge cells. The one another opposite surfaces of the electrodes can,

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like a ^ lasina display board, layers of an electric have insulating material.

The electrode groups can either be used as groups of so-called matrix electrodes or as a combination of a first Group of segment electrodes and a second group of the opposite .Elektrode or electrodes be.

A known control circuit of the type described above is at least one switching transistor for each of the Electrodes of the display board. The switching transistors have to withstand a relatively high voltage, for example 140V. In addition, logic circuitry is necessary to provide pulses to each switching transistor. It is therefore inevitable that the circuit becomes extensive and expensive, especially in those cases in which the Display panel has a large number, for example 200 or more, electrodes in at least one of the electrode groups. In a known control circuit of the type described above, it is necessary to choose between the power consumption the circuit arrangement and the shutdown speed of the Switching transistors to make a compromise. This compromise leads to a serious limitation in further development of the technology of plasma display panels and makes it impossible to use the so-called time division control to be used for a plasma display panel with segment elec-

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dull for a large number of digits, such as 10 or more to press.

Accordingly, the invention has the object of providing a circuit arrangement to create a relative for the control of an electrode group of a gas discharge display panel small number of switching transistors on v / eist.

Another object of the invention is to provide a To provide control circuit of the type described above which operates with a small number of logic circuits v / can earth.

An additional object of the invention is to to provide a control circuit of the type described above which is operable at high speed.

A circuit for driving an electrode group of a gas discharge display panel with a pair of electrode groups on both sides of the gas discharge space has, according to the invention, a voltage source, a number of PNP transistors, a number of NPN transistors and a first device for connecting the emitter electrodes of the ΡΠΡ -Transistors to the positive terminal of the voltage source and a second device for connecting the emitter electrodes of the NPN transistors to a reference potentialL A first number of conductors is connected to the collector electrical.

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connected to that of the PNP transistors. A second number of Conducting is to the collector electrodes of the NPN transistors tied together. Each of the second number of conductors intersects the first number of conductors and thereby forms a number of matrix points. At each of the trix points, the first and second conductors are switched in the forward direction by a Diode connected together. Each electrode of the above-described one electrode group is associated with the diode tied together. The circuit further comprises a first number of diodes and a second number of diodes connected to the first and second numbers of conductors are connected accordingly.

In a control circuit according to the invention, a Electrode group of a gas discharge display panel either time-division multiplexed or selectively according to the desired one Display can be controlled. A similar circuit can be used to control the other group of electrodes Scoreboard can be used.

Accordingly, the circuit according to the invention for driving an electrode group of a gas discharge display panel a number of PNP and NPN transistors. the Emitter electrodes of the PNP transistors are connected to the positive terminal of a DC voltage source and the emitter electrodes of the NPN transistors connected to ground. The collector electrodes of the PNP transistors and those of the NPN transistors

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disturb are interconnected by diode devices via matrix points, which at the point of intersection of a number of corresponding with the collector electrodes of the PNP transistors connected first conductors and a number of correspondingly connected to the collector electrodes of the NPN transistors. bonded second conductors are formed. The individual electrodes of a group of electrodes on the gas discharge display panel are connected to the diode devices. The circuit also includes a number of first diodes and a number of second diodes that match the number of first and second conductors are connected accordingly.

Embodiments of the invention are based on the drawings described in more detail. 3s show:

1 shows a first embodiment, partly in a block diagram, the control circuit according to the invention and

Fig. 2 in a similar representation, partly in a block diagram, a second embodiment of a control circuit according to the invention.

In Fig. 1 is a circuit arrangement of a first according to the invention Embodiment for controlling a group of electrodes with 256 electrodes of a plasma display panel 10 is shown. This plasma display panel has two electrode

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groups on opposite sides of a gas discharge space, as described in the introduction to the description, are arranged. The circuit arrangement has 1b PUP transistors 11., 11, - ,, ... and 11 ^ g and 16 KPK transistors 12., 12p, ... and 12./- on. To simplify the description the indices of the Re ihone lenient e are omitted in the following, if the reference number or numbers refer to the relevant element or elements more in the general as referring to one or more selected. The emitter electrodes 9 of the PIT? -Transistors 11 are with a Voltage source 15 with a voltage v. connected that at least equal to the ignition voltage of the gas discharge space is. The emitter electrodes S of the OPKi transistors 12 are connected to earth. 16 first conductors 16 are with the collector electrodes 7 of the corresponding PKP transistors 11 are connected. 1β second conductors 17 are with the collector electrodes of the corresponding NPK transistors 12 connected. Although the first conductors 16 are shown parallel to one another, while the second conductors 17 run perpendicular to the first conductors 16, it is only necessary that each of the second conductors in connection with the first conductors 16 form 16 matrix points. The first and second conductors 1b and 17 therefore form a total of 256 matrix points 5. At each of the matrix points 5, the first and second conductors 1b and 17, as shown in FIG Fig. 1 is shown, connected to one another by two diodes 18 and 19 connected in series. The diodes 18 and 19 are switched in the forward direction ^.

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Connection points 4 of the diodes 18 and 19, a total of 256, are connected to the electrodes of an electrode group of the plasma display panel 10 via lines A.

The circuit arrangement shown in FIG in addition, a clock or timer 20 for generating pulses with a repetition frequency, as follows is explained. The pulses are fed to a first hexadecimal counter 21, whose frequency-divided output signal a second hexadecimal counter 22 is supplied. As is known, a hexadecimal counter consists of four levels. Those from the corresponding level of the first hexadecimal counter The four-bit signals derived from 21 are fed to a first hexadecimal decoder 26. Similar signals are sent by the Second hexadecimal counter 22 is supplied to a second hexadecimal decoder 27. Each hexadecimal decoder 26 or 27 energizes one after the other its 16 output terminals. The circuit arrangement also has 16 NAND gates 31. Each NAND gate 31 has an input which is connected to the corresponding output terminal of the decoder 26 and which by the corresponding Output terminals of the decoder 26 delivered signals is released. Similarly, there is 16 AND gates 32 one of the inputs is connected to the corresponding output terminal of the decoder 27 and is controlled by the the corresponding output terminals of the second hexadecimal decoder 27 released signals derived. An impulse signal

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The signal source 35 supplies a pair of two-phase pulse trains <M and Ψ 2 to the second input terminals of the NAD gates 31 and the AND gates 32, respectively. The output terminals of the NAND gates 31 are connected to the base electrode of the PNP transistors 11 via capacitors 14. The output terminals of the AND gates 32 are similarly connected to the base electrodes 2 of the NPN transistors 12 via RC circuits 28. The circuit arrangement also has 16 first diodes 36, the cathodes of which are connected to the first conductors I63, and 16 second diodes 37, the anodes of which are connected to the second conductors 17. Anode electrodes of the first diodes 36 are connected to ground. The cathode electrodes of the second diodes 37 are connected to the voltage source 15 of the voltage V ₁ .

To simplify the description, it is assumed during operation that the first and two diodes 36 and 37 are not used. It is also assumed that the first output terminals of the hexadecimal decoders 26 and 27 are energized. The two-phase pulse series * P 1 and ψ 2 turn on the first PNP and NPN transistors H ₁ and 12 ^ alternately via the corresponding NAND gates 31 ^ and AND gates 32 ₂ . The first line A ₁ is therefore supplied with a pulse voltage which rises approximately to the positive voltage V ₁ on each leading edge of each pulse of the first pulse train 1 and returns approximately to ground potential on each leading edge of each pulse of the second pulse train 2. Lines A ₂ to A ₁ ^ are at this time essentially

8th
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chen kept at Brdpotential, since the connection points of the diodes 19 ″ with the second conductors 17 are at üirdpotential when the NPN transistor 12. is conductive, and since the diodes 19 prevent these lines from being supplied with the positive voltage V. is fed through the diodes 13 and 19 of the first charge A ^ when the PNP transistor 11. is switched on. The 17th, 33rd ... and 241st line A ^, A ", ... and ΑρΛ ,, are essentially kept at the positive voltage V., since the connection points of the first diodes 18 with the first conductor 16 are supplied with the positive voltage V. when the PNP transistors 11. are switched on, and since the first diodes 13 are supplied with Prevent ground potential to these lines from being fed to the first line A ₁ when the NPW transistor 12 is switched on. No specific electrical potential is fed to the other lines, such as the 256th line Apcg. such as Α., the one with the mat rixpunkt is connected, which leads to a pair of alternately switched PNP and NPN transistors, the pulse voltage V. is supplied, while the other lines, such as Ap, A. "and Apcg, no pulse voltage is supplied. It is therefore possible with the circuit arrangement shown to supply the pulse voltage V cyclically to an electrode group of the plasma display panel 10 and to cause a display of one or more desired digits, letters and / or the like. By the other electrode group selectively a pulse voltage with reverse Polarity in relation to time to

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Pulse voltage V ^ is supplied.

In connection with the above-mentioned operation of the erfinduiigs according to the switching it is necessary that the following three points should be considered. First, iat en for a flicker-free display in the case of a time multiple-pin control necessary, one voltage pulse series for each electrode of the group concerned at a frequency of the order of 50 Hz or more. The repetition rate of the clock pulses should therefore be 11ε-gsn at 12.8 kHz (50 Hz χ 256) or more. Second, for a sufficiently bright display, it is necessary that 2000 or more pulses per second are applied to each electrode of the corresponding group. The pole sequence the pulse series φ1 or co2 should therefore be approximately 500 kHz (2 kHz χ 256) or more. It has been shown that the Ausfülirungsform shown in Fig. 1 for the display electrodes supplied pulses have a switching time of 0.2 μεοο and that stable operation is possible even at a frequency of 700 kHz.

Third, the impulse voltage or voltages induces, which are fed to one or more electrodes of a gas discharge display panel, in the adjacent ones Electrostatic induction or coupling between the electrodes unwanted electrical currents. Through this the result is a false display, especially on the electrodes that are connected to the lines to which

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there is no specific potential. Furthermore, the electrostatic induction or coupling causes an increase in the voltage across the electrodes 18 and 19, which reduces the breakdown voltage; can exceed. The first and second diodes 36 and 17 keep the voltages at the electrodes 4, which are connected by lines, in the range from 0 to "V". In other words, the voltages at the electrodes 4 never reach a level which is below the ground potential, ΐ, ε is due to the first diodes 36, and never exceed the voltage V ^, which is due to the second diodes 37 is due.

2 shows a second embodiment of the circuit according to the invention for driving 512 column electrodes a Pissiaa display panel 10 with matrix electrodes is shown, Similar elements or parts of the embodiment according to Fig. are with the same reference numbers and letters as in Fig. 1 marked. It is assumed here that the display panel 10 has eight row electrodes which are time division multiplexed controlled, and that the column electrodes are divided into 16 groups, each consisting of 32 electrodes, to which one or more pulse trains are selectively fed. In Fig. 2, the second hexadecimal counter the circuit arrangement according to FIG. 1 is replaced by an octal counter 41. The three-3it output of the octal counter 41 is fed to a octal decoder 42. A group of driver circuits 43 which are conventionally implemented

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can generate output signals that the row electrodes drive in a time division multiplex process as a function of the output signal generated by the octal decoder 42. That The output signal of the decoder 42 occurs cyclically at its eight output terminals. The circuit arrangement also has a data memory 45 in which 32-bit binary signals are representative for the numbers, letters and / or to be displayed. Like. Either manually or temporarily stored in another way will. A second series of pulses is fed to the clock generator 20 in order to control the data memory 45. The memory 45 supplies a 32-bit signal to a buffer memory 46 every time the output signal of the hexadecimal decoder 26 moves from one contact to the next.

Furthermore, the circuit arrangement in FIG. 2 has PKP and ITPK transistors 38 and 39, the collectors of which are connected to the anode of the first diode 36 and the cathode of the second diode 37, respectively. The emitters of the transistors 38 and 39 are connected to a voltage source 40 of a positive voltage Vp which is lower than the voltage V .., for example half as large. The pulse series ψ2 is fed to the base electrodes from the pulse signal source 35 via capacitors. If, therefore, the electrode 4 ^ is selected, ie the first output terminal of the decoder 26 and of the buffer memory 46 are energized, the first conductor I6. is held at the voltage V by the transistor 11 ^, the first conductors 16 ₂ to I6.g through transistor 38 at voltage Vp, the second line

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ter 17-1 through the transistor 12. to ground potential and the second conductors 17o to 17 ^ ₂ through the transistor 39 to the voltage Vg.

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Claims (1)

P a t e η t a η s ρ r ti c h e 1. J circuit for controlling an electrode group of a Phase dischargeξ display panel with a pair of electrode groups on both oeiteii of the üt.sentledungsraumes and with one Voltage source, characterized in that dai3 she has a number of PI;? - Trans is or en (11) with one each Emitter (9) and collector electrodes (7); a number of KPM transistors (12) each with one Emitter (8) and collector electrodes (o) j first means for connecting the emitter electrodes (9) of the PNP transistors (11) to the positive pole of the Voltage source (15) and the emitter electrodes (8) of the NPN transistors (12) with soil; corresponding to the number of PHP transistors (11) first conductor (16) that connects to the collector electrode (7) of the PMP transistors (11) are connected; second conductor corresponding to the number of KPM transistors (12) (17) j those with the collector electrode (6) of the KPN transistors (12) are connected and in connection with the first conductors (16) in each case matrix points (5) corresponding to the number the PNP transistors (11) form; 609886/0790 in the forward direction switched diodes (13, 19) each with (4) ■ a predetermined circuit point at each matrix point (5) the first and second conductors (16, 17) together associate; second means (A) for connecting the predetermined points to the corresponding electrodes of the electrode group ; corresponding to the number of ¹ PNP transistors (11) first diodes (36) which are connected to the first conductors (16) in order to keep their potential at a predetermined level and corresponding to the number of NPi -; - transistors (12) second diodes (37) connected to the second conductors (17) to keep their potential at a predetermined level. - 15 S09885 / 0790